四川省芦山—宝兴地区花岗石石材产出地质特征及其品质

本文扼要阐明四川省芦山－宝兴地区花岗石石材产出地质特征的基础上，重点讨论花岗石石材的品种、规模和质量。     

南昆仑结合带盲矿西沟早白垩世高分异花岗岩的发现及其地质意义

In order to explore the petrogenesis and tectonic settings of the Early Cretaceous magmatic rocks in the South Kunlun Suture Zone, we systematically analyzed the petrography, geochronology, and whole-rock geochemistry of the granites in the Mangkuangxigou area. The Mangkuangxigou granites are featured by presence of tourmaline and mica in the rocks and formed at 113.4 to 117.5 Ma based on the zircon LA-ICP-MS U-Pb dating results. These granites have high contents of SiO2 (72.03% to 75.10%) and alkali (Na2O+K2O=7.62% to 7.86%), but low contents of MgO (0.13% to 0.56%) and TiO2 (0.08% to 0.30%), and belong to strongly peraluminous (A/CNK=1.20 to 1.24) and high-K calc-alkaline to calc-alkaline series. Meanwhile, these rocks are rich in Rb, Th and U, but depleted in Ba, Sr and Ti. They have low REE concentrations and show relatively enriched LREE and significant negative Eu anomalies (δEu=0.18 to 0.31). The SiO2 contents of the granites are negatively correlated with that of TiO2, Fe2O3T MgO, Al2O3, Th, and Rb, defining their affinities to highly fractionated S-type granites. Generation of the Mangkuangxigou granites was related to the partial melting of crustal rocks caused by underplating of mantle-derived magmas in an extensional setting. Such magmatism in the northern Tibetan Plateau was a far-reaching response caused by the closure of the Neo-Tethys Bangonghu-Nujiang Ocean, which may associate with a great W-Sn mineralization potential. © 2023 Science Press. All rights reserved.     

胶西北中生代花岗岩中黑云母和角闪石成分特征及成岩成矿意义

在详细的野外地质和岩相学观察基础上,对胶西北中生代玲珑期、郭家岭期和伟德山期花岗岩中的黑云母和角闪石进行了系统的化学成分研究。结果显示,玲珑期,研究区中部和南部花岗岩中的黑云母为铁叶云母和铁质黑云母,其MgO为4.07%~6.53%,具有壳源型黑云母的特征;北部主要为铁质黑云母和镁质黑云母,MgO介于9.13%~11.57%之间,具壳幔混源型的特征;郭家岭期和伟德山期花岗岩中的黑云母以铁质黑云母和镁质黑云母为主,MgO为7.62%~15.38%,均为壳幔混源型,其中的角闪石均属于钙质角闪石,M值为0.44~0.76。暗色矿物成分显示玲珑期花岗岩的源区物质主要为壳源,郭家岭期和伟德山期的以壳源为主,有少量幔源组分参与。三期花岗岩中黑云母结晶温度主要集中于550~700℃,而角闪石的结晶温度为600~750℃,从玲珑期到郭家岭期再到伟德山期,即从早到晚,黑云母的结晶温度有升高的趋势;全铝压力计估算结果显示,黑云母和角闪石的结晶压力具有降低的趋势。郭家岭期和伟德山期花岗岩中黑云母结晶过程中的氧逸度分别为-15.0~-9.0和-15.3~-8.8,明显比玲珑期的(-17.5~-13.2)高。结合胶西北金矿的时空分布特征,认为花岗岩结晶过程中较高的氧逸度和幔源物质的参与可能是有利于金矿化的重要条件之一。     

新疆西准噶尔苏云河钼矿床含矿岩体地球化学和年代学

苏云河钼矿床位于新疆西准噶尔巴尔鲁克山西段,容矿岩石为二长花岗岩和二长花岗斑岩。这些花岗岩具有类似的地球化学特征:富集Rb、Th、U和LREE,相对亏损Ba、P、Ti,属于高钾钙碱性I型花岗岩系列,局部经历过强烈的分离结晶作用。LA-ICPMS锆石U-Pb定年结果显示苏云河钼矿区的成岩年龄为309.3~310.2 Ma,这表明与成矿有关的岩浆活动发生于晚石炭世。黑云母的Ti温度计表明Ⅰ号和Ⅲ号岩体的结晶温度相近,为695~728℃;而Ⅱ号岩体的结晶温度较低,为642~668℃。同时根据角闪石-斜长石压力计获得Ⅰ号和Ⅲ号岩体的结晶压力为(3.0~3.9)×108Pa。综合地球化学研究表明,苏云河钼矿区3个岩体均形成于岛弧环境。此外,以苏云河钼矿床为代表的巴尔鲁克山成矿带与哈萨克斯坦境内的巴尔喀什成矿带在岩石地球化学、成岩成矿时代等方面具有许多类似的特点,表明巴尔鲁克山成矿带可能是巴尔喀什成矿带在中国境内的延伸。     

朝鲜~19亿年侵入岩的岩石类型与构造背景初探

朝鲜半岛北部广泛发育~19亿年侵入岩,这些岩浆岩可以分为三个系列,分别为似斑状花岗岩系列(多为I型,以妙香山岩体为代表,年龄1900~1840Ma)、S型花岗岩系列(以嘉山岩体为代表,本文获得1862±5Ma锆石U-Pb年龄)和正长岩系列(以龙浦岩体为代表,本文获得1857±2Ma锆石U-Pb年龄)。似斑状花岗岩系列(I型花岗岩)大致对应朝鲜地质学家定义的Myohyangsan(妙香山)杂岩,以发育钾长石巨斑为特征,与麻粒岩相变质的火山岩-沉积岩系关系密切;S型花岗岩系列大致对应Ryonhwasan(莲花山)杂岩,以发育石榴石和堇青石等矿物为特征,与麻粒岩相变质的副变质岩共生:这说明前者可能与变质火山岩系相关,而后者可能和副变质岩相关。正长岩系列,朝鲜地质学家称为Sakju(朔州)杂岩,分布较为局限,仅见于朔州以及博川-定州之间,也见于邻区辽东,多为岩株。这三个系列岩浆岩稍早或者同期于角闪岩相-麻粒岩相变质(本文获得甑山"群"变质锆石U-Pb年龄1844±2Ma)。邻区辽东-吉南及胶东地区也发育这三个系列岩浆岩,但这两个地区~21亿年岩浆作用更为广泛。朝鲜半岛南部发育大量同期岩浆岩,但岩石类型以似斑状花岗岩为主,并发育紫苏花岗岩和斜长岩。我们推测,朝鲜半岛南北两侧基底属性存在差异,可能对应不同的古陆(华北与华南古陆)。综合分析表明,朝鲜~19亿年前广泛发育I型和S型花岗岩,并有幔源岩浆作用,同时发育正长岩类,并且这些岩浆活动与区域高级变质作用时代接近。考虑到本区存在太古宙基底,我们推测本区在古元古代可能处于类似现今活动大陆边缘弧背景。     

新疆塔里木北缘新元古代最晚期岩浆事件

报道了塔里木库鲁克塔格地区新元古代晚期花岗闪长岩和钾长花岗岩的锆石U-Pb年龄和Hf同位素组成。花岗闪长岩锆石U-Pb谐和年龄为630.1±1.3Ma,钾长花岗岩锆石U-Pb谐和年龄为630.6±1.3Ma。Hf同位素组成表明,这2种岩石主要来自古老（中）基性地壳的重熔,可能有部分地幔物质的加入。结合已有的研究表明,650~615Ma期间的岩浆活动代表了塔里木地块新元古代最晚期的岩浆活动,是Rodinia超大陆解体过程中的产物,与泛非造山事件无关。塔里木地块自新元古代中期到早寒武世,持续接受了被动大陆边缘沉积,表明在这一时期塔里木为冈瓦那大陆之外独立的大陆块体,或是位于冈瓦那大陆最边缘的稳定大陆块体。     

Geochemistry,petrogenesis and tectonic setting of the peraluminous granites in the nacheng gold deposit,Yongning, Guangdong北大核心

The Nacheng granite locates in the Yong ning area, Guangdong Province. This paper studied petrographical and chronological characteristics of this granite as well as its petrogenesis and geological significance. The Nacheng granite mainly consists of quartz (40%-50%), orthoclase (25%-30%), palgioxlase (15%-20%) with minor accessory minerals of quartz apatite and magnetite. Geochemical analyses show that the manziying granite has high content of SiO2 (75. 56%) , K2O (4.72%), Al2O3 (13. 34%) and total alkali (Na2O+K2O=7. 49%), but relatively low MgO (0. 04%-1. 29%) and CaO (0. 39%-2. 21%). The ratios of K2O/Na 2O are generally higher than 1. The Rittmann indexes are between 1-2. 43, belonging to the high-K calc-alkaline series. The values of A/CNK vary from 1. 12 to 1. 32 with an average of 1. 10, showing the characteristics of peraluminous S type granites. Trace element analyses show that the Nacheng granite has relatively high REE content of 82. 6 × 10-6 225. 68 × 10-1, and displays right-inclined V-shape REE patterns with relatively high fractionations of LREE and HREE[(La/Yb)N = 1. 51-9. 66] and pronounced negative Eu anomalies (δEu = 0. 31-0. 74) in the chondrite-normalized REE diagrams, suggesting a typical crust-derived grandite. The magmas may be divided into two types: "low-temperature" type from mudstones and "high-temperature" type from sandstones. The Nacheng granites were formed from the post-orogenic tectonic setting.     

内蒙古西部甜水井地区中二叠世A型花岗岩

内蒙古北山甜水井地区龙脊山—神蛇岭岩体，总体呈北西向长椭圆状，面积大于100km^2。按岩石谱系单位划分为一单元含斑细粒黑云母二长花岗岩、二单元含斑中细粒黑云母二长花岗岩和三单元中细粒花岗岩,归并为一龙脊山序列。岩石富硅碱，ALK在7．23％～8．37％．AKI小于1,A／CNK=1．01～1．07；OX较高．在0．47～0．83。相对富集大离子亲石元素、轻稀土元素，亏损Ba、Nb、Sr、Zr、Ti。稀土配分曲线呈现显著的“V”字型。副矿物组合为Mt-Ap-Zi型。由早单元到晚单元。向酸碱性增强方向演化，显示深源浅成铝质A型(A2型)花岗岩特征。各类构造环境判别图解投点．具造山后或后造山特征。同位素测年(锆石U-Pb法)为267．1Ma。反映本区中二叠世碰撞造山作用的存在。中二叠晚期已转入稳定的陆内发展环境。     

Magmatic evolution of Li–F, rare-metal granites: a case study of melt inclusions in the Khangilay complex, Eastern Transbaikalia (Russia)

We report compositions of homogenized quartz-hosted melt inclusions from a layered sequence of Li-, F-rich granites in the Khangilay complex that document the range of melt evolution from barren biotite granites to Ta-rich, lepidolite–amazonite–albite granites. The melt inclusions are crystalline at room temperature and were homogenized in a rapid-quench hydrothermal apparatus at 200 MPa before analysis. Homogenization runs determined solidus temperatures near 550 °C and full homogenization between 650 and 750 °C. The compositions of inclusions, determined by electron microprobe and Raman spectroscopy (for H₂O), show regular overall trends of increasing differentiation from the least-evolved Khangilay units to apical units in the Orlovka intrusion. Total volatile contents in the most-evolved melts reach over 11 wt.% (H₂O: 8.6 wt.%, F: 1.6 wt.%, B₂O₃: 1.5 wt.%). Concentrations of Rb range from about 1000 to 3600 ppm but other trace elements could not be measured reliably by electron microprobe. The resulting trends of melt evolution are similar to those described by the whole-rock samples, despite petrographic evidence for albite- and mica-rich segregations previously taken as evidence for post-magmatic metasomatism.

Melt variation trends in most samples are consistent with fractional crystallization as the main process of magma evolution and residual melt compositions plot at the granite minimum in the normative Qz–Ab–Or system. However, melts trapped in the highly evolved pegmatitic samples from Orlovka deviate from the minimum melt composition and show compositional variations in Al, Na and K that requires a different explanation. We suggest that unmixing of the late-stage residual melt into an aluminosilicate melt and a salt-rich dense aqueous fluid (hydrosaline melt) occurred. Experimental data show the effectiveness of this process to separate K (aluminosilicate melt) from Na (hydrosaline melt) and high mobility of the latter due to its low viscosity and relatively low density may explain local zones of albitization in the upper parts of the granite.     

REE Abundance and REE Minerals in Granitic Rocks in the Nanling Range,Jiangxi Province,Southern China,and Generation of the REE‐rich Weathered Crust Deposits

Studies of Mesozoic granites associated with rare earth element (REE)‐rich weathered crust deposits in southernmost Jiangxi Province indicate that they have high‐K to shoshonite compositions and belong to ilmenite‐series I‐type granites. Of the studied rocks at 59–292 ppm of bulk REE content, the highest are seen in the biotite granites of Dingnan (358, 429 ppm) and mafic biotite granite of the Wuliting Granite (344 ppm) near the Dajishan tungsten mine, both areas where weathered‐crust REE deposits occur. REE‐bearing accessory minerals in these granites are mainly zircon, apatite and allanite, and REE‐fluorocarbonates are common. REE enrichment occurs in the rims of apatite crystals, and in fluorocarbonates that occur along grain boundaries of and cracks in major silicate minerals, and in fluorocarbonates that replaced altered biotite. It is therefore thought that a major part of the REE content of these granites was concentrated during deuteric activity, rather than during magmatic crystallization. The crack‐filling REE‐fluorocarbonates could subsequently have been easily leached out and deposited in weathered crust developed during a long period of exposure.